This is speculative, but I think cryonics could be useful to fix the biological body as well. Cryogenic conditions are easier for certain types of things, for example some types of molecular nanotech might not work well under warm conditions but should work fine if kept cold. Also, more finely detailed printing could be possible under cryogenic conditions. It might turn out to be the most reliable way to replace the body when it gets old—vitrify, cut out the brain, then print everything else around it. When printing in a cold state to begin with, there would be less concern of overexposure to cryoprotectants or achieving perfusion (you could use less toxic, harder to perfuse cryoprotectants such as trehalose).
This is speculative, but I think cryonics could be useful to fix the biological body as well. Cryogenic conditions are easier for certain types of things, for example some types of molecular nanotech might not work well under warm conditions but should work fine if kept cold. Also, more finely detailed printing could be possible under cryogenic conditions. It might turn out to be the most reliable way to replace the body when it gets old—vitrify, cut out the brain, then print everything else around it. When printing in a cold state to begin with, there would be less concern of overexposure to cryoprotectants or achieving perfusion (you could use less toxic, harder to perfuse cryoprotectants such as trehalose).